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ABSTRACT
This report relates the conduct of a collaborative research project devoted to the design and validation of an innovative ship propeller concept equipped with composite blades attached to its hub. Bringing together research laboratories in hydrodynamics and numerical simulation, and SMEs with expertise in mechanical or hydrodynamic modelling and calculations, and in the design of tooling for the production of composite parts, the project led to the development of methods and processes for the manufacture of a propeller with a composite blade, some of whose performance was validated during a sea trail on a test ship.
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Read the articleAUTHORS
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Frédérique LE LAY: Composite materials expert - Naval Group– 5, rue de l'Halbrane – 44340 Bouguenais – France
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Jean-François SIGRIST: Research engineer, science journalist - Expertise & communication scientifiques (eye-π) – 4, place Foire-le-Roi – 37000 tours – France
INTRODUCTION
Large ships are propelled by propellers, most of which are made of metallic materials. Shipbuilders and naval architects are also interested in other materials, such as composites, as they offer a number of advantages (in particular, lightness and the ability to produce parts with mechanical properties adapted to stresses). The design of a propeller with composite blades is, however, not without its share of technical problems. A major international shipbuilder has launched a multi-year research program to develop the methodological tools needed to design, produce and test an innovative composite propeller concept.
The "HéliCo" project brought together industrial and academic experts from the technological research center of a major group, two academic laboratories and three SMEs in the shipbuilding sector. It has resulted in the development of calculation methods for sizing and analyzing the hydrodynamic and mechanical behavior of deformable load-bearing profiles, with modeling of fluid-structure interactions; the development of a system for attaching composite blades to a metal hub; the development of a manufacturing process for composite blades, using the RTM process; and the in situ validation of a small-scale thruster prototype tested on a passenger transport ship.
Field: innovation, collaborative research.
Companies involved: shipbuilders (naval industry, marine energies), software publishers (scientific computing, digital simulation, HPC), design offices (design of propulsion and energy recovery systems).
Technologies/methods involved: numerical modeling, scientific computing, finite elements, composite materials, carbon epoxy.
Sectors: mechanical engineering, naval engineering, energy production.
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KEYWORDS
innovation | composite | numerical simulation | propeller
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HéliCo project: developing and designing an innovative thruster
Project background and objectives
Bibliography
Website
Bureau Veritas – NI663: "Propeller in Composite Material", March 2023.
https://erules.veristar.com/dy/data/bv/pdf/663-NI_2023_03.pdf
Julie DANET, "More current in the blades", Sciences Ouest, February 2015.
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French Mechanical Association (AFM)
European Composites Days (JEC)
Copropel
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Computers & Fluidsc
https://www.sciencedirect.com/journal/computers-and-fluids/
Computer Methods in Applied Mechanics and Engineering
http://www.elsevier.com/locate/cma
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